Scientists have sequenced the genetic code of Aspergillus oryzae, a fungus commonly used to make fermented foods and animal feed. This fungus produces useful enzymes that break down plant materials, making nutrients more available. The completed genome sequence helps researchers ensure the fungus is safe for food production by checking for any potential health risks.
Scientists sequenced the complete genetic blueprint of a beneficial fungus called Alternaria alternata that lives inside African marula tree leaves. This fungus produces many different bioactive compounds with potential medical applications. The genetic information is now publicly available for researchers to study how this fungus makes these useful compounds and develop new treatments.
Scientists have sequenced the complete genetic blueprints of 35 fungal strains belonging to Pyricularia species and related genera, which cause devastating blast diseases in crops like rice and wheat. By analyzing genetic differences between strains that infect different grass species, researchers found that most Pyricularia oryzae strains show strong preferences for specific host plants. These new genome resources will help scientists understand how fungal pathogens evolve and adapt to new plant hosts, potentially improving disease management strategies.
Scientists developed a new method to accurately identify and distinguish different strains of button mushrooms using genetic markers derived from core genes. This method is more accurate and simpler than previous approaches and can be applied to other mushroom species and fungi. The research helps mushroom farmers and breeders properly identify cultivars and protect their varieties from unauthorized propagation.
Scientists have sequenced and analyzed the complete genomes of four species of Mucor fungus that cause serious infections in humans. Using advanced long-read sequencing technology, they created high-quality genetic blueprints for these organisms, which will help doctors better identify which Mucor species is causing infections and enable faster diagnosis and treatment of these dangerous fungal infections.
Researchers created a complete genetic blueprint of a poisonous mushroom called Trichoderma cornu-damae that can be mistaken for medicinal mushrooms. Using advanced DNA sequencing techniques, they mapped all seven chromosomes and identified over 8,500 genes in this toxic fungus. This genetic map will help scientists understand how the mushroom produces dangerous toxins that harm rapidly growing cells. The work provides important information for identifying and studying this poisonous species.
Scientists have sequenced the complete genetic blueprint of a fungus called Diaporthe vaccinii that causes serious disease in blueberry plants. Using advanced DNA sequencing technology, they created a high-quality map of the fungus’s 60.2 million base pair genome. This genetic information will help researchers understand how the fungus causes disease and potentially develop better ways to protect blueberry crops from this costly plant pathogen.